CELL DIVISION IN THE DINOFLAGELLATE GAMBIERDISCUS TOXICUS IS PHASED TO THE DIURNAL CYCLE AND ACCOMPANIED BY ACTIVATION OF THE CELL CYCLE REGULATORY PROTEIN,CDC2 KINASE1

The cell division cycle in several pelagic dinoflagellate species has been shown to be phased with the diurnal cycle, suggesting that their cell cycle may be regulated by a circadian clock. In this study, we examined the cell cycle of an epibenthic dinoflagellate, Gambierdiscus toxicus Adachi and Fukuyo (Dinophyceae), and found that cell division was similarly phased to the diurnal cycle. Cell division occurred during a 3-h window beginning 6 h after the onset of the dark phase. Cell cycle progression in higher eukaryotes is regulated by a cell cycle regulatory protein complex consisting of cyclin and the cyclin-dependent kinase CDC2. In this report, we identified a CDC2-like kinase in G. toxicus that displays activity in vitro against a known substrate of CDC2 kinase, histone H1. As in higher eukaryotes, CDC2 kinase was expressed constitutively in G. toxicus throughout the cell cycle, but it was activated only late in the dark phase, concurrent with the presence of mitotic cells. These results indicate that cell division in G. toxicus is regulated by molecular controls similar to those found in higher eukaryotes.     

Molecular Evolution Allows Bypass of the Requirement for Activation Loop Phosphorylation of the Cdc28 Cyclin-Dependent Kinase

Many protein kinases are regulated by phosphorylation in the activation loop, which is required for enzymatic activity. Glutamic acid can substitute for phosphothreonine in some proteins activated by phosphorylation, but this substitution (T169E) at the site of activation loop phosphorylation in the Saccharomyces cerevisiae cyclin-dependent kinase (Cdk) Cdc28p blocks biological function and protein kinase activity. Using cycles of error-prone DNA amplification followed by selection for successively higher levels of function, we identified mutant versions of Cdc28p-T169E with high biological activity. The enzymatic and biological activity of the mutant Cdc28p was essentially normally regulated by cyclin, and the mutants supported normal cell cycle progression and regulation. Therefore, it is not a requirement for control of the yeast cell cycle that Cdc28p be cyclically phosphorylated and dephosphorylated. These CDC28 mutants allow viability in the absence of Cak1p, the essential kinase that phosphorylates Cdc28p-T169, demonstrating that T169 phosphorylation is the only essential function of Cak1p. Some growth defects remain in suppressed cak1 cdc28 strains carrying the mutant CDC28 genes, consistent with additional nonessential roles for CAK1.     

Mutational analysis of Cak1p, an essential protein kinase that regulates cell cycle progression

In Saccharomyces cerevisiae, entry into S phase requires the activation of the protein kinase Cdc28p through binding with cyclin Clb5p or Clb6p, as well as the destruction of the cyclin-dependent kinase inhibitor Sic1p. Mutants that are defective in this activation event arrest after START, with unreplicated DNA and multiple, elongated buds. These mutants include cells defective in CDC4, CDC34 or CDC53, as well as cells that have lost all CLB function. Here we describe mutations in another gene, CAK1, that lead to a similar arrest. Cells that are defective in CAK1 are inviable and arrest with a single nucleus and multiple, elongated buds. CAK1 encodes a protein kinase most closely related to the Cdc2p family of protein kinases. Mutations that lead to the production of an inactive kinase that can neither autophosphorylate, nor phosphorylate Cdc28p in vitro are also incapable of rescuing a cell with a deletion of CAK1. These results underscore the importance of the Cak1p protein kinase activity in cell cycle progression. Received: 2 January 1997 / Accepted: 20 June 1997     

Cdc18/CDC6 activates the Rad3-dependent checkpoint in the fission yeast

A screen for genes that can ectopically activate a Rad3-dependent checkpoint block over mitosis in fission yeast has identified the DNA replication initiation factor cdc18 (known as CDC6 in other organisms). Either a stabilized form of Cdc18, the Cdc18-T6A phosphorylation mutant, or overexpression of wild type Cdc18, activate the Rad3-dependent S-M checkpoint in the apparent absence of detectable replication structures and gross DNA damage. This cell cycle block relies on the Rad checkpoint pathway and requires Chk1 phosphorylation and activation. Unexpectedly, Cdc18-T6A induces changes in the mobility of Chromosome III, affecting the size of a restriction fragment containing rDNA repeats and producing aberrant nucleolar structures. Recombination events within the rDNA appear to contribute at least in part to the cell cycle delay. We propose that an elevated level of Cdc18 activates the Rad3-dependent checkpoint either directly or indirectly, and additionally causes expansion of the rDNA repeats on Chromosome III.     

Loss of meiotic rereplication block in Saccharomyces cerevisiae cells defective in Cdc28p regulation

Cdc28p is the major cyclin-dependent kinase in Saccharomyces cerevisiae. Its activity is required for blocking the reinitiation of DNA replication during mitosis. Here, we show that under conditions where Cdc28p activity is improperly regulated--either through the loss of function of the Schizosaccharomyces pombe wee1 ortholog Swe1p or through the expression of a dominant CDC28 allele, CDC28AF--diploid yeast cells are able to complete several rounds of premeiotic DNA replication within a single meiotic cell cycle. Moreover, a percentage of mutant cells exhibit a "multispore" phenotype, possessing the ability to package more than four spores within a single ascus. These multispored asci contain both even and odd numbers of viable spores. In order for meiotic rereplication and multispore formation to occur, cells must initiate homologous recombination and maintain proper chromosome cohesion during meiosis I. Rad9p- or Rad17p-dependent checkpoint mechanisms are not required for multispore formation and neither are the B-type cyclin Clb6p and the cyclin-dependent kinase inhibitor Sic1p. Finally, we present evidence of a possible role for a Cdc55p-dependent protein phosphatase 2A in initiating meiotic replication.     

Mutations in CDC14 result in high sensitivity to cyclin gene dosage in Saccharomyces cerevisiae

We screened for mutations that resulted in lethality when the G1 cyclin Cln2p was overexpressed throughout the cell cycle in Saccharomyces cerevisiae. Mutations in five complementation groups were found to give this phenotype, and three of the mutated genes were identified as MEC1, NUP170, and CDC14. Mutations in CDC14 may have been recovered in the screen because Cdc14p may reduce the cyclin B (Clb)-associated Cdc28 kinase activity in late mitosis, and Cln2p may normally activate Clb-Cdc28 kinase activity by related mechanisms. In agreement with the idea that cdc14 mutations elevate Clb-Cdc28 kinase activity, deletion of the gene for the Clb-Cdc28 inhibitor Sic1 caused synthetic lethality with cdc14-1, as did the deletion of HCT1, which is required for proteolysis of Clb2p. Surprisingly, deletion of the gene for the major B-type cyclin, CLB2, also caused synthetic lethality with the cdc14-1 mutation. The clb2 cdc14 strains arrested with replicated but unseparated DNA and unseparated spindle pole bodies; this phenotype is distinct from the late mitotic arrest of the sic1::TRP1 cdc14-1 and the cdc14-1 hct1::LEU2 double mutants and of the cdc14 CLN2 overexpressor. We found genetic interactions between CDC14 and the replication initiator gene CDC6, extending previous observations of interactions between the late mitotic function of Cdc14p and control of DNA replication. We also describe genetic interactions between CDC28 and CDC14. Received: 24 May 1999 / Accepted: 19 October 1999     

Studying the DNA damage response using in vitro model systems

Exogenous and endogenous insults continuously damage DNA. DNA damage must be detected in order to prevent loss of vital genetic information. Cells respond to DNA damage by activating checkpoint pathways that delay the progression through the cell cycle, promote DNA repair or induce cell death. A regulatory network of proteins has been identified that participate in DNA damage checkpoint pathways. Central to this network are ATM, ATR and the Mre11/Rad50/Nbs1 (MRN) complex. Detailed biochemical analysis of ATM, ATR and the MRN dependent DNA damage responses has taken advantage of several in vitro model systems to understand the detailed mechanisms underlying their function. Here we describe some recent findings obtained analysing these pathways using in vitro model systems. In particular we focus on the studies performed in the Xenopus laevis egg cell free extract, which recapitulates the DNA damage response in the context of the cell cycle.     

Stability of Rad51 recombinase and persistence of Rad51 DNA repair foci depends on post-translational modifiers,ubiquitin and SUMO

The DNA double-strand breaks are particularly deleterious, especially when an error-free repair pathway is unavailable, enforcing the error-prone recombination pathways to repair the lesion. Cells can resume the cell cycle but at the expense of decreased viability due to genome rearrangements. One of the major players involved in recombinational repair of DNA damage is Rad51 recombinase, a protein responsible for presynaptic complex formation. We previously showed that an increased level of this protein promotes the usage of illegitimate recombination. Here we show that the level of Rad51 is regulated via the ubiquitin-dependent proteolytic pathway. The ubiquitination of Rad51 depends on multiple E3 enzymes, including SUMO-targeted ubiquitin ligases. We also demonstrate that Rad51 can be modified by both ubiquitin and SUMO. Moreover, its modification with ubiquitin may lead to opposite effects: degradation dependent on Rad6, Rad18, Slx8, Dia2, and the anaphase-promoting complex, or stabilization dependent on Rsp5. We also show that post-translational modifications with SUMO and ubiquitin affect Rad51's ability to form and disassemble DNA repair foci, respectively, influencing cell cycle progression and cell viability in genotoxic stress conditions. Our data suggest the existence of a complex E3 ligases network that regulates Rad51 recombinase's turnover, its molecular activity, and access to DNA, limiting it to the proportions optimal for the actual cell cycle stage and growth conditions, e.g., stress. Dysregulation of this network would result in a drop in cell viability due to uncontrolled genome rearrangement in the yeast cells. In mammals would promote the development of genetic diseases and cancer.     

Phosphatases,DNA Damage Checkpoints and Checkpoint Deactivation

Cells have evolved intricate and specialized responses to DNA damage, central to which are the DNA damage checkpoints that arrest cell cycle progression and facilitate the repair process. Activation of these damage checkpoints relies heavily on the activity of Ser/Thr kinases, such as Chk1 and Chk2 (Saccharomyces cerevisiae Rad53), which are themselves activated by phosphorylation. Only more recently have we begun to understand how cells disengage the checkpoints to reenter the cell cycle. Here, we review progress toward understanding the functions of phosphatases in checkpoint deactivation in S. cerevisiae, focusing on the non-redundant roles of the type 2A phosphatase Pph3 and the PP2C phosphatases Ptc2 and Ptc3 in the deactivation of Rad53. We discuss how these phosphatases may specifically recognize different phosphorylated forms of Rad53 and how each may independently regulate different facets of the checkpoint response. In conjunction with the independent dephosphorylation of other checkpoint proteins, such regulation may allow a more tailored response to DNA damage that is coordinated with the repair process, ultimately resulting in the resumption of growth.     

A conservative pathway for coordination of cell wall biosynthesis and cell cycle progression in plants

The mechanism that coordinates cell growth and cell cycle progression remains poorly understood; in particular, whether the cell cycle and cell wall biosynthesis are coordinated remains unclear. Recently, cell wall biosynthesis and cell cycle progression were reported to respond to wounding. Nonetheless, no genes are reported to synchronize the biosynthesis of the cell wall and the cell cycle. Here, we report that wounding induces the expression of genes associated with cell wall biosynthesis and the cell cycle, and that two genes, AtMYB46 in Arabidopsis thaliana and RrMYB18 in Rosa rugosa, are induced by wounding. We found that AtMYB46 and RrMYB18 promote the biosynthesis of the cell wall by upregulating the expression of cell wall-associated genes, and that both of them also upregulate the expression of a battery of genes associated with cell cycle progression. Ultimately, this response leads to the development of curled leaves of reduced size. We also found that the coordination of cell wall biosynthesis and cell cycle progression by AtMYB46 and RrMYB18 is evolutionarily conservative in multiple species. In accordance with wounding promoting cell regeneration by regulating the cell cycle, these findings also provide novel insight into the coordination between cell growth and cell cycle progression and a method for producing miniature plants.     

Involvement of cyclin-dependent kinase CDK1/CDC28 in regulation of cell cycle

Cyclin-dependent kinases (CDKs) are a family of enzymes essential for the progression of the cells through the cell cycle in eukaryotes. Moreover, genetic stability-maintaining processes, such as check-point control and DNA repair, require the phosphorylation of a wide variety of target substrates by CDK. In budding yeast Saccharomyces cerevisiae, the key role in the cell cycle progression is played by CDK1/CDC28 kinase. This enzyme is the most thoroughly investigated. In this review the involvement of CDC28 kinase in regulation of the cell cycle is discussed in the light of newly obtained data.     

Phosphatase Complex Pph3/Psy2 Is Involved in Regulation of Efficient Non-Homologous End-Joining Pathway in the Yeast Saccharomyces cerevisiae

One of the main mechanisms for double stranded DNA break (DSB) repair is through the non-homologous end-joining (NHEJ) pathway. Using plasmid and chromosomal repair assays, we showed that deletion mutant strains for interacting proteins Pph3p and Psy2p had reduced efficiencies in NHEJ. We further observed that this activity of Pph3p and Psy2p appeared linked to cell cycle Rad53p and Chk1p checkpoint proteins. Pph3/Psy2 is a phosphatase complex, which regulates recovery from the Rad53p DNA damage checkpoint. Overexpression of Chk1p checkpoint protein in a parallel pathway to Rad53p compensated for the deletion of PPH3 or PSY2 in a chromosomal repair assay. Double mutant strains Δpph3/Δchk1 and Δpsy2/Δchk1 showed additional reductions in the efficiency of plasmid repair, compared to both single deletions which is in agreement with the activity of Pph3p and Psy2p in a parallel pathway to Chk1p. Genetic interaction analyses also supported a role for Pph3p and Psy2p in DNA damage repair, the NHEJ pathway, as well as cell cycle progression. Collectively, we report that the activity of Pph3p and Psy2p further connects NHEJ repair to cell cycle progression.     

CDC28 phosphorylates Cac1p and regulates the association of chromatin assembly factor i with chromatin

Chromatin Assembly Factor I (CAF-I) plays a key role in the replication-coupled assembly of nucleosomes. It is expected that its function is linked to the regulation of the cell cycle, but little detail is available. Current models suggest that CAF-I is recruited to replication forks and to chromatin via an interaction between its Cac1p subunit and the replication sliding clamp, PCNA, and that this interaction is stimulated by the kinase CDC7. Here we show that another kinase, CDC28, phosphorylates Cac1p on serines 94 and 515 in early S phase and regulates its association with chromatin, but not its association with PCNA. Mutations in the Cac1p-phosphorylation sites of CDC28 but not of CDC7 substantially reduce the in vivo phosphorylation of Cac1p. However, mutations in the putative CDC7 target sites on Cac1p reduce its stability. The association of CAF-I with chromatin is impaired in a cdc28–1 mutant and to a lesser extent in a cdc7–1 mutant. In addition, mutations in the Cac1p-phosphorylation sites by both CDC28 and CDC7 reduce gene silencing at the telomeres. We propose that this phosphorylation represents a regulatory step in the recruitment of CAF-I to chromatin in early S phase that is distinct from the association of CAF-I with PCNA. Hence, we implicate CDC28 in the regulation of chromatin reassembly during DNA replication. These findings provide novel mechanistic insights on the links between cell-cycle regulation, DNA replication and chromatin reassembly.     

中心体蛋白Centlein的敲除促进细胞周期进程

中心体是大部分动物细胞的微管组织中心,它确保了有序的细胞周期进程以及染色体的精确分离,我们之前报道了中心体蛋白Centlein作为一个分子连接,与C-Nap1和Cep68一起形成复合物维持中心体的连接. 然而,关于Centlein的其他功能我们还知之甚少. 在本研究中,建立了Centlein的敲除细胞系,并且运用RNA-seq技术分析了敲除细胞系和正常野生型细胞系之间转录水平的差异. 发现Centlein敲除细胞系中细胞周期相关基因PLK1、CCNB1、CCNA2和CDC20的表达量上调,流式结果又表明Centlein的敲除促进了细胞周期进程. 同时发现Centlein与PLK1之间存在细胞内相互作用,于是我们提出了Centlein通过与PLK1的作用参与细胞周期进程.